Downlink indicator channel processing in a wireless system base station

ABSTRACT

A transmitter comprises indicator channel processing circuitry configured to process indicator channel codewords for transmission in a base station of a wireless system. The indicator channel processing circuitry performs a plurality of processing operations on the indicator channel codewords in a specified processing sequence, with the plurality of processing operations comprising at least modulation, scrambling, spreading and combining. In the specified processing sequence, the scrambling operation is performed for at least a given one of the indicator channel codewords prior to the modulation and spreading operations for that codeword or subsequent to the combining operation for that codeword. For example, the specified processing sequence may comprise the scrambling, modulation, spreading and combining operations performed in that order for at least the given codeword, or the modulation, spreading, combining and scrambling operations performed in that order for at least the given codeword.

BACKGROUND

Wireless systems in the cellular context are currently being implementedusing fourth generation (4G) standards. These 4G standards include LongTerm Evolution (LTE) standards developed by the 3G Partnership Project(3GPP). LTE cellular systems make use of an Internet protocol (IP) basedpacket core referred to as Evolved Packet Core (EPC). The EPCinterconnects multiple base stations within the system. A given basestation, also referred to as an evolved Node B (eNB), communicates overan air interface with multiple user terminals. Individual user terminalsare also referred to as user equipment (UE).

The air interface between an eNB and UE in an LTE cellular systemincludes a variety of uplink and downlink channels. See, for example,3GPP TS 36.211, V9.1.0, 3rd Generation Partnership Project TechnicalSpecification, Group Radio Access Network, Evolved Universal TerrestrialRadio Access (E-UTRA), Physical Channels and Modulation (Release 9),March 2010, which is incorporated by reference herein. One such channelis a downlink hybrid automatic repeat request (ARQ) channel referred toas PHICH (“Physical Hybrid ARQ Indicator Channel”).

In conventional PHICH processing, hybrid ARQ indicator (HI) codewordsfrom a given PHICH group are each modulated, then subject to spreadingand scrambling operations, then mapped onto a number of layers, and thenprecoded. The precoded layers from multiple PHICH codewords are thencombined in a PHICH symbol combiner. Each PHICH group can hold up toeight codewords. Additional details regarding these and otherconventional PHICH processing operations can be found in Section 6.9 ofthe above-cited 3GPP TS 36.211 document, at pages 57-61.

LTE system channels such as PHICH are subject to strict latencyrequirements. This can unduly increase the memory and computationalrequirements of the base station, leading to higher costs and increasedpower consumption.

SUMMARY

Illustrative embodiments of the invention provide improved processing ofPHICH channels or other types of indicator channels in a base station ofa wireless system, such as an LTE wireless cellular system. For example,one or more such embodiments may be configured to modify the ordering ofcertain PHICH processing operations relative to conventionalarrangements, in a manner that substantially reduces PHICH processingtime. This makes it easier to meet strict LTE latency requirements,while also reducing base station cost and power consumption.

In one embodiment, a base station transmitter in a wireless systemcomprises indicator channel processing circuitry configured to processindicator channel codewords for transmission from the base station touser terminals. The indicator channel processing circuitry performs aplurality of processing operations on the indicator channel codewords ina specified processing sequence, with the plurality of processingoperations comprising at least modulation, scrambling, spreading andcombining. In the specified processing sequence, the scramblingoperation is performed for at least a given one of the indicator channelcodewords prior to the modulation and spreading operations for thatcodeword or subsequent to the combining operation for that codeword.

For example, the specified processing sequence may comprise thescrambling, modulation, spreading and combining operations performed inthat order for at least the given codeword, or the modulation,spreading, combining and scrambling operations performed in that orderfor at least the given codeword. In these and other processingsequences, certain of the processing operations may overlap with oneanother. As one possible instance of such overlapping of processingoperations, at least the modulation and spreading operations may be atleast partially overlapped with one another.

In other embodiments, the processing operations may further compriserepetition, layer mapping and precoding operations, and the specifiedprocessing sequence may comprise one of the following two sequences:repetition, scrambling, modulation, spreading, combining, layer mappingand precoding operations performed in that order, and repetition,modulation, spreading, combining, scrambling, layer mapping andprecoding operations performed in that order.

As a further example, the indicator channel processing circuitry in oneor more embodiments may comprise, for each of a plurality of indicatorchannels in a group of indicator channels, a repetition and scramblingmodule configured to receive indicator channel codewords and to generatescrambled bits from the codewords, and a modulation and spreading moduleconfigured to receive the scrambled bits and to generate spread symbolsfrom the scrambled bits. The indicator channel processing circuitry inan embodiment of this type may further comprise a symbol combiner sharedby each of the indicator channels in the group and configured to combinespread symbols from the modulation and spreading modules associated withthe respective indicator channels, and a layer mapping and precodingmodule configured to receive the combined symbols from the symbolcombiner and to generate outputs corresponding to respective ones of aplurality of precoded layers.

As yet another example, the indicator channel processing circuitry inone or more embodiments may comprise, for each of a plurality ofindicator channels in a group of indicator channels, a repetition moduleconfigured to receive indicator channel codewords and to generaterepeated bits from the codewords, and a modulation and spreading moduleconfigured to receive the repeated bits and to generate spread symbolsfrom the repeated bits. The indicator channel processing circuitry in anembodiment of this type may further comprise a symbol combiner shared byeach of the indicator channels in the group and configured to combinespread symbols from the modulation and spreading modules associated withthe respective indicator channels, a scrambling module configured toreceive the combined symbols from the symbol combiner and to generatescrambled combined symbols, and a layer mapping and precoding moduleconfigured to receive the scrambled combined symbols from the scramblingmodule and to generate outputs corresponding to respective ones of aplurality of precoded layers.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing an illustrative embodiment of awireless system that incorporates improved downlink indicator channelprocessing.

FIG. 2 shows a more detailed view of a portion of a base stationtransmitter of the FIG. 1 system.

FIGS. 3 and 4 show different embodiments of downlink indicator channelprocessing circuitry that may be implemented in the base station of FIG.2.

DETAILED DESCRIPTION

Embodiments of the invention will be illustrated herein in conjunctionwith exemplary wireless systems which include one or more base stationseach configured to communicate with multiple user terminals in aparticular manner. It should be understood, however, that the disclosedtechniques are more generally applicable to any wireless systemapplication in which it is desirable to provide improved processing ofPHICH channels or other types of indicator channels. For example, theinvention can be implemented in a wide variety of other types ofwireless systems, including systems outside of the LTE cellular context,such as WiMAX systems, Wi-Fi systems, etc.

FIG. 1 shows a wireless communication system 100 in an illustrativeembodiment. The system 100 includes a plurality of base stations 102-1,102-2, . . . 102-M, each arranged to communicate with multiple userterminals 110. It is assumed without limitation that the wireless system100 comprises an LTE cellular system. The base stations 102 aretherefore also referred to in this embodiment as respective evolved NodeB (eNB) elements, and the user terminals 110 are also referred to asuser equipment (UE). The base stations 102 are coupled to an evolvedpacket core (EPC) 104, which may include, for example, one or moreconventional gateways and mobility management entities of a type wellknown in the art. The EPC 104 provides connectivity between the basestations 102 and one or more external networks, in this embodimentillustratively comprising Internet 106.

A given one of the user terminals 110 may comprise, by way of example, amobile telephone, a computer, or any other type of user communicationdevice. The term “user terminal” as used herein is therefore intended tobe construed broadly, so as to encompass a variety of different types ofmobile stations, subscriber stations or, more generally, communicationdevices.

It is to be appreciated that the system 100 as illustrated in FIG. 1 isjust one exemplary configuration of a wireless cellular system, andnumerous alternative configurations of system elements may be used. Forexample, other embodiments of the invention may include additional oralternative elements of a type commonly associated with conventionalsystem implementations.

The base stations 102 and user terminals 110 in the system 100communicate over uplink and downlink channels of the type specified inthe 3GPP LTE standards documents, such as the above-cited 3GPP TS 36.211document. These channels include at least one physical hybrid ARQindicator channel (PHICH). Embodiments of the invention configure one ormore of the base stations 102 so as implement improved processing ofPHICH channels. Such PHICH channels may be viewed as examples of whatare more generally referred to herein as “indicator channels.” In theseembodiments, the ordering of certain PHICH processing operations ismodified relative to conventional arrangements, in a manner thatsubstantially reduces PHICH processing time, thereby making it easier tomeet strict LTE latency requirements, while also reducing base stationcost and power consumption.

FIG. 2 shows a downlink transmitter 200 in a particular one of the basestations 102-1. The transmitter 200 comprises PHICH processing circuitry202 for providing the above-noted improved processing of PHICH channels.One or more other base stations 102 may also be configured to include asimilar downlink transmitter. Each of the base stations 102 may befurther assumed to include additional uplink and downlink transceiverelements and related components of a conventional nature for supportingcommunications over other types of channels within the system 100.

The PHICH processing circuitry 202 may be viewed as an example of whatis more generally referred to herein as “indicator channel processingcircuitry” that is configured to process indicator channel codewords fortransmission in a base station of a wireless system. As will bedescribed below in conjunction with the illustrative embodiments, suchindicator channel processing circuitry performs a plurality ofprocessing operations on indicator channel codewords in a specifiedprocessing sequence, with the processing operations comprising at leastmodulation, scrambling, spreading and combining. More particularly, inthe specified processing sequence the scrambling operation may beperformed prior to the modulation and spreading operations, as in theillustrative embodiment of FIG. 3, or subsequent to the combiningoperation, as in the illustrative embodiment of FIG. 4. Both of theseexemplary arrangements lead to significantly reduced processing time andtherefore improved overall performance relative to the conventionalPHICH processing as set forth in the above-cited 3GPP TS 36.211document.

As shown in FIG. 2, the PHICH processing circuitry 202 receives hybridARQ indicator (HI) codewords associated with one or more PHICH groups.The HI codewords are also referred to herein as PHICH codewords. EachPHICH group in this embodiment is assumed to comprise N indicatorchannels, denoted HI 1 through HI N, where N may take on values up toand including eight in the 3GPP TS 36.211 document but may take on othervalues in embodiments of the present invention. Also, there may be Kdifferent PHICH groups that are processed by the PHICH processingcircuitry 202, where a particular one of the groups is indexed by thevariable k, where k=1, 2, . . . K.

The outputs of the PHICH processing circuitry 202 in the presentembodiment comprise processed indicator channel codewords that may becharacterized as being in the form of multiple precoded layers. Theprecoded layers are applied as inputs to a resource mapping module 204,which may also map inputs for other channels from other processingcircuitry not specifically shown. After the resource mapping in module204, corresponding orthogonal frequency division multiplexed (OFDM)signals are generated in OFDM signal generation module 206, and theresulting OFDM signals are applied to antenna ports 208 for transmissionover an air interface of the system 100 to the user terminals 110. Suchresource mapping and OFDM signal generation operations may be performedin a well-known conventional manner. In other embodiments, a variety ofother techniques may be used to transmit indicator channel codewordsbetween a base station and user terminals.

The downlink transmitter 200 further comprises a processor 210 coupledto a memory 212. At least a portion of the PHICH processing circuitry202 may be implemented as one or more processing modules, eachcomprising computer program code that is stored in the memory 212 andexecuted by the processor 210. The processor and memory elements of thetransmitter 200 need not be dedicated exclusively to the transmitter 200and accordingly may be shared with one or more other transmitters,receivers or other components of the base station 102-1. For example,these processor and memory elements may represent respective generalizedprocessing and memory resources of the base station that performoperations for multiple base station components.

The processor 210 may comprise, for example, one or moremicroprocessors, application- specific integrated circuits (ASICs),field-programmable gate arrays (FPGAs), digital signal processors(DSPs), systems-on-chip (SOCs) or other types of processing devices, aswell as portions or combinations of such elements.

The memory 212 may comprise, for example, electronic memory such asrandom access memory (RAM) or read-only memory (ROM), magnetic memory,optical memory or other types of storage elements, as well as portionsor combinations of such elements. System memory elements such as memory212 are considered examples of what are also referred to herein ascomputer-readable storage media that store computer program code, ormore generally computer program products having executable program codeembodied therein. Such program code when executed in the base station102-1 of the wireless system 100 causes the base station to perform atleast a portion of the functionality of the downlink transmitter 200,and more particularly to implement at least a portion of the PHICHcodeword processing. Thus, PHICH processing circuitry as that term isused herein may encompass circuitry associated with processor 210 andmemory 212.

Illustrative embodiments of the PHICH processing circuitry 202 will nowbe described in greater detail with reference to FIGS. 3 and 4. In eachof these embodiments, the PHICH processing circuitry performs aplurality of processing operations on the HI codewords in a specifiedprocessing sequence, with the processing operations comprising at leastmodulation, scrambling, spreading and combining. More particularly, inthe FIG. 3 embodiment, the scrambling operation is performed prior tothe modulation and spreading operations, while in the FIG. 4 embodimentthe scrambling operation is performed subsequent to the combiningoperation.

Thus, in the FIG. 3 embodiment, the specified processing sequencecomprises at least the scrambling, modulation, spreading and combiningoperations performed in that order, and in the FIG. 4 embodiment, thespecified processing sequence comprises at least the modulation,spreading, combining and scrambling operations performed in that order.This ordering of operations should not be viewed as precluding at leastpartial overlap of certain of the processing operations. For example, atleast the modulation and spreading operations in a given embodiment maybe at least partially overlapped with one another. Despite any suchoverlap, scrambling is still performed in these embodiments prior to themodulation and spreading operations, or subsequent to the combiningoperation.

It should be noted in this regard that the ordering of the processingoperations in the illustrative embodiments may be viewed as referring toordering with respect to a given codeword. Accordingly, performingscrambling prior to modulation and spreading may be viewed as performingscrambling for a given codeword prior to modulating and spreading thatcodeword.

Referring now more specifically to FIG. 3, the PHICH processingcircuitry 202 comprises initial module sets 300-1 through 300-N, withone such module set associated with each of the N indicator channelswithin a given PHICH group denoted as group k. In this embodiment, thescrambling operation is performed on bits of a given one of the HIcodewords prior to performing the modulation and spreading operations onthat codeword. In addition, because the scrambling operation in thisembodiment is performed prior to spreading, a repetition operation isperformed on the bits of the given indicator channel codeword prior toperforming the scrambling operation on that codeword. As will becomeapparent, the processing operations in the FIG. 3 embodiment moreparticularly comprise repetition, layer mapping and precodingoperations, and the specified processing sequence comprises therepetition, scrambling, modulation, spreading, combining, layer mappingand precoding operations performed in that order.

The PHICH processing circuitry 202 as shown in FIG. 3 comprises, foreach of the N indicator channels in the group k of indicator channels, arepetition and scrambling module 302 configured to receive indicatorchannel codewords and to generate scrambled bits from those codewords,and a modulation and spreading module 304 configured to receive thescrambled bits and to generate spread symbols from the scrambled bits.The modules 302 and 304 for a given one of the N indicator channels arepart of the corresponding module set 300. Thus, for example, modules302-1 and 304-1 are part of the module set 300-1 for the first indicatorchannel of group k, and modules 302-N and 304-N are part of the moduleset 300-N for the final indicator channel of group k.

In the FIG. 3 embodiment, as indicated above, the scrambling operationis performed prior to spreading, and thus a repetition operation isperformed prior to scrambling. For example, assume that a given HIcodeword comprises three identical bits, either 000 or 111. In aconventional arrangement, each bit of the codeword is modulated into asymbol, such that after modulation there are three symbols representingthe codeword, and the symbols are then spread by a factor of four toconvert the three symbols into 12 spread symbols, which is followed bythe scrambling operation performed on the 12 spread symbols. Becausescrambling is done prior to modulation and spreading in the FIG. 3embodiment, the repetition operation takes as input the three identicalbits comprising the given HI codeword and outputs 12 identical bits,either 000000000000 or 111111111111, so as to provide a 12-bit output tothe scrambling operation for each codeword. The same type of repetitionoperation is performed in module 402 of the FIG. 4 embodiment, as willbe described.

The PHICH processing circuitry 202 further comprises a symbol combiner306 shared by each of the N indicator channels in group k. The symbolcombiner 306 is configured to combine spread symbols from the modulationand spreading modules 304 associated with the respective indicatorchannels. Also included in the PHICH processing circuitry 202 is a layermapping and precoding module 308 configured to receive the combinedsymbols from the symbol combiner 306 and to generate outputscorresponding to respective ones of a plurality of precoded layers,suitable for resource mapping and signal generation in transmitter 200.

These outputs of PHICH processing circuitry 202 are consistent withthose specified by the above-cited 3GPP TS 36.211 document, butprocessing time in generating the outputs is significantly reducedrelative to the conventional arrangement. For example, the amount ofprocessing required per time slot in this embodiment is reduced at leastin part because the number of required mapping and precoding executionsis reduced by a factor corresponding to the number of indicator channelsin the group.

With reference now to FIG. 4, the PHICH processing circuitry 202comprises initial module sets 400-1 through 400-N, with one such moduleset associated with each of the N indicator channels within a givenPHICH group denoted as group k. In this embodiment, the scramblingoperation is performed on combined symbols from multiple HI codewordsassociated with respective indicator channels in group k, subsequent toperforming the combining operation for those codewords. As will becomeapparent, the processing operations in the FIG. 4 embodiment moreparticularly comprise repetition, layer mapping and precodingoperations, and the specified processing sequence comprises therepetition, modulation, spreading, combining, scrambling, layer mappingand precoding operations performed in that order.

The PHICH processing circuitry 202 as shown in FIG. 4 comprises, foreach of the N indicator channels in the group k of indicator channels, arepetition module 402 configured to receive indicator channel codewordsand to generate repeated bits from those codewords, and a modulation andspreading module 404 configured to receive the repeated bits and togenerate spread symbols from the repeated bits. The repeated bitsgenerated by the repetition module 402 comprise 12 identical bits,either 000000000000 or 111111111111, for each of the codewords, asmentioned previously in the context of the FIG. 3 embodiment. Themodules 402 and 404 for a given one of the N indicator channels are partof the corresponding module set 400. Thus, for example, modules 402-1and 404-1 are part of the module set 400-1 for the first indicatorchannel of group k, and modules 402-N and 404-N are part of the moduleset 400-N for the final indicator channel of group k.

The PHICH processing circuitry 202 further comprises a symbol combiner406 shared by each of the N indicator channels in group k. The symbolcombiner 406 is configured to combine spread symbols from the modulationand spreading modules 404 associated with the respective indicatorchannels. Also included in the PHICH processing circuitry 202 is ascrambling module 407 configured to receive the combined symbols fromthe symbol combiner and to generate scrambled combined symbols, and alayer mapping and precoding module 408 configured to receive thescrambled combined symbols from the scrambling module 407 and togenerate outputs corresponding to respective ones of a plurality ofprecoded layers, suitable for resource mapping and signal generation intransmitter 200.

As in the FIG. 3 embodiment, these outputs of PHICH processing circuitry202 in the FIG. 4 embodiment are consistent with those specified by theabove-cited 3GPP TS 36.211 document, but processing time in generatingthe outputs is significantly reduced relative to the conventionalarrangement. For example, the amount of processing required per timeslot in the FIG. 4 embodiment is reduced at least in part because thenumber of required scrambling executions is reduced by a factorcorresponding to the number of indicator channels in the group.

Additional details regarding exemplary PHICH processing operations suchas modulation, scrambling, spreading, combining, layer mapping andprecoding that can be adapted for use in the embodiments of FIGS. 3 and4 may be found in the above-cited 3GPP TS 36.211 document.Alternatively, other types and arrangements of these and otherprocessing operations may be used to process indicator channel codewordsas described herein.

It is to be appreciated that the particular indicator channel processingcircuitry arrangements and associated processing operations as shown inFIGS. 3 and 4 may be varied in other embodiments. Numerous alternativearrangements of hardware, software and firmware in any combination maybe used to implement the described indicator channel processingfunctionality.

Also, although described primarily in the context of PHICH processing inan LTE wireless cellular system, the disclosed techniques can be adaptedfor use with a wide variety of other types of indicator channels usedfor communication between a base station and user terminals in awireless system. Such indicator channels may comprise, for example,other types of ARQ channels, although it is to be appreciated that theterm “indicator channel” as used herein is not limited to ARQ channels.

Indicator channel processing circuitry or portions thereof in accordancewith embodiments of the invention may be implemented in the form of oneor more integrated circuits suitable for installation within basestation equipment. Thus, PHICH processing circuitry 202 may beimplemented as a separate integrated circuit, or as a combination ofmultiple integrated circuits.

The term “transmitter” as used herein is intended to be broadlyconstrued, so as to encompass, for example, a set of PHICH processingmodules and one or more related elements such as resource mappers andsignal generators. It may but need not encompass additional elementsassociated with transmission of indicator channel codewords, such asupconverters, filters, antennas, etc. A base station transmitter maytherefore be implemented in the form of an integrated circuit.

In a given integrated circuit implementation, identical die aretypically formed in a repeated pattern on a surface of a semiconductorwafer. Each die may include at least a portion of indicator channelprocessing circuitry as described herein, and may include otherstructures or circuits. The individual die are cut or diced from thewafer, then packaged as an integrated circuit. One skilled in the artwould know how to dice wafers and package die to produce integratedcircuits. Integrated circuits so manufactured are considered embodimentsof the invention.

Again, it should be emphasized that the embodiments described herein areintended to be illustrative only. For example, the particulararrangement of base stations, user terminals, networks and other systemelements as shown in FIG. 1 may be varied in alternative embodiments.Also, other types of circuitry elements or processing modules may beused to implement indicator channel processing functionality asdisclosed herein. These and numerous other alternative embodimentswithin the scope of the following claims will be readily apparent tothose skilled in the art.

What is claimed is:
 1. An apparatus comprising: a transmitter comprisingindicator channel processing circuitry configured to process indicatorchannel codewords for transmission in a base station of a wirelesssystem; wherein the indicator channel processing circuitry performs aplurality of processing operations on the indicator channel codewords ina specified processing sequence, the plurality of processing operationscomprising at least modulation, scrambling, spreading and combining; andwherein in the specified processing sequence the scrambling operation isperformed for at least a given one of the indicator channel codewordsprior to the modulation and spreading operations for that codeword orsubsequent to the combining operation for that codeword.
 2. Theapparatus of claim 1 wherein the indicator channel codewords compriserespective physical hybrid ARQ indicator channel (PHICH) codewords. 3.The apparatus of claim 1 wherein the scrambling operation is performedon bits of the given indicator channel codeword prior to performing themodulation operation on that codeword.
 4. The apparatus of claim 3wherein a repetition operation is performed on the bits of the givenindicator channel codeword prior to performing the scrambling operationon that codeword.
 5. The apparatus of claim 1 wherein the scramblingoperation is performed on combined symbols from a plurality of indicatorchannel codewords associated with respective indicator channels in agroup of said indicator channels subsequent to performing the combiningoperation for those codewords.
 6. The apparatus of claim 1 wherein thespecified processing sequence comprises at least the scrambling,modulation, spreading and combining operations performed in that orderfor at least the given codeword, with at least the modulation andspreading operations being at least partially overlapped with oneanother for the given codeword.
 7. The apparatus of claim 1 wherein thespecified processing sequence comprises at least the modulation,spreading, combining and scrambling operations performed in that orderfor at least the given codeword, with at least the modulation andspreading operations being at least partially overlapped with oneanother for the given codeword.
 8. The apparatus of claim 1 wherein theprocessing operations further comprise at least repetition, layermapping and precoding operations, and wherein the specified processingsequence comprises one of the following two sequences: at least therepetition, scrambling, modulation, spreading, combining, layer mappingand precoding operations performed in that order for the given codeword;and at least the repetition, modulation, spreading, combining,scrambling, layer mapping and precoding operations performed in thatorder for the given codeword.
 9. The apparatus of claim 1 wherein theindicator channel processing circuitry comprises, for each of aplurality of indicator channels in a group of indicator channels, atleast the following modules: a repetition and scrambling moduleconfigured to receive indicator channel codewords and to generatescrambled bits from said codewords; and a modulation and spreadingmodule configured to receive the scrambled bits and to generate spreadsymbols from the scrambled bits.
 10. The apparatus of claim 9 whereinthe indicator channel processing circuitry further comprises a symbolcombiner shared by each of the indicator channels in the group andconfigured to combine spread symbols from the modulation and spreadingmodules associated with the respective indicator channels.
 11. Theapparatus of claim 10 wherein the indicator channel processing circuitryfurther comprises a layer mapping and precoding module configured toreceive the combined symbols from the symbol combiner and to generateoutputs corresponding to respective ones of a plurality of precodedlayers.
 12. The apparatus of claim 1 wherein the indicator channelprocessing circuitry comprises, for each of a plurality of indicatorchannels in a group of indicator channels, at least the followingmodules: a repetition module configured to receive indicator channelcodewords and to generate repeated bits from said codewords; and amodulation and spreading module configured to receive the repeated bitsand to generate spread symbols from the repeated bits.
 13. The apparatusof claim 12 wherein the indicator channel processing circuitry furthercomprises a symbol combiner shared by each of the indicator channels inthe group and configured to combine spread symbols from the modulationand spreading modules associated with the respective indicator channels.14. The apparatus of claim 13 wherein the indicator channel processingcircuitry further comprises: a scrambling module configured to receivethe combined symbols from the symbol combiner and to generate scrambledcombined symbols; and a layer mapping and precoding module configured toreceive the scrambled combined symbols from the scrambling module and togenerate outputs corresponding to respective ones of a plurality ofprecoded layers.
 15. An integrated circuit comprising the apparatus ofclaim
 1. 16. A base station comprising the apparatus of claim
 1. 17. Theapparatus of claim 1 wherein the transmitter further comprises: aprocessor; and a memory coupled to the processor; wherein at least aportion of the indicator channel processing circuitry is implemented asone or more processing modules each comprising computer program codethat is stored in the memory and executed by the processor.
 18. A methodcomprising: processing indicator channel codewords in a base station ofa wireless system; and transmitting the processed indicator channelcodewords from the base station; wherein the processing step furthercomprises performing a plurality of processing operations on theindicator channel codewords in a specified processing sequence, theplurality of processing operations comprising at least modulation,scrambling, spreading and combining; and wherein in the specifiedprocessing sequence the scrambling operation is performed for at least agiven one of the indicator channel codewords prior to the modulation andspreading operations for that codeword or subsequent to the combiningoperation for that codeword.
 19. The method of claim 18 wherein theprocessing operations further comprise at least repetition, layermapping and precoding operations, and wherein the specified processingsequence comprises one of the following two sequences: at least therepetition, scrambling, modulation, spreading, combining, layer mappingand precoding operations performed in that order for the given codeword;and at least the repetition, modulation, spreading, combining,scrambling, layer mapping and precoding operations performed in thatorder for the given codeword.
 20. A computer program product havingexecutable computer program code embodied therein, wherein the computerprogram code when executed in the base station of the wireless systemcauses the base station to perform the steps of the method of claim 18.